Artist rendering of SES-15 (manufactured by Boeing and launched using Ariane 5 rocket in Q2 2017) Building the Next Generation Satellite fleet Martin Halliwell, Chief Technical Officer INVESTOR DAY 2015, 17 June 2015
Summary SES is procuring the next generation of satellites today SES s satellites are at the core of an evolving and expanding global network SES is driving further technical innovation to deliver tomorrow s next generation satellite 1
SES s new satellite mantra Issue/opportunity solution ~50% of total payload mass is traditionally propellant; of which ~⅔ burnt in a few days 1 Light in Electric propulsion weight Efficient in 2 beams Communication ecosystem is evolving with additional need for more efficient, affordable data connectivity solutions HTS capacity Digital processing 3 Fast to market Currently takes ~3 years to design, build and launch a GEO satellite New launch vehicles Exploring other possibilities (e.g. modular construction, reusable rockets) 2
Advancing capabilities through innovation Seven satellites under procurement Q3 2015 2016 2017 SES-9 SES-10 SES-11 SES-12 SES-14 SES-15 SES-16/ GovSat (1) Payload Type Shaped Shaped Shaped 14 GHz HTS + Shaped 12 GHz HTS + Shaped 10 GHz HTS + Shaped Fully steerable spot beams Digital Processing 2.6 GHz 2.5 GHz Satellite Propulsion Electric Chemical Chemical Electric Electric Electric Chemical Launch Vehicle Falcon 9 Falcon 9 Falcon 9 Ariane 5 Falcon 9 Ariane 5 Falcon 9 Combining industry-leading procurement standards with the latest satellite innovations 1) Procured by LuxGovSat 3
Optimising mass to generate launch cost savings Mass [ ] and launch cost savings achieved by using electric propulsion SES-12 SES-14 SES-15 Mass if chemical propulsion used Mass if chemical propulsion used Satellite Mass Mass (actual) ~40% mass saving Mass (actual) ~40% mass saving Mass if chemical propulsion used ~50% mass saving Mass (actual) Launch solution Launched with Co-passenger ~40% launch cost saving Smaller Launch Vehicle (Falcon 9) ~30% launch cost saving Launched with Co-passenger ~40% launch cost saving Electric propulsion also provides longer fuel at negligible marginal cost 4
Device/ application Connected nodes Infrastructure Communication ecosystem is evolving Traditional ecosystem mainly connected linear broadcast customers GEO Teleport Direct-to-Home Television Device / Application 5
Device/ application Connected nodes Infrastructure Communication ecosystem is evolving Modern ecosystem also includes deeper networks/applications with a multitude of connectivity options GEO MEO Fixed Microwave Fiber Optics Cellular Aeronautical Remote Enterprise Enterprise Teleport Direct-to-Home WiFi Maritime Data Centres Big Data Machine-to- Machine Computing Television Personal Computing Mobile Devices Public WiFi E-Commerce 6
Improving spectrum efficiency with hybrid satellites SES-15 shaped beam and spot beam coverage 4x (1) 1x Shaped beams provide wide broadcast coverage Spot beams deliver focused capacity for point-to-point or mesh needs Spot beam architectures maximise spectrum re-use providing greater theoretical bits/hz 1) Capacity on a linked basis for point-to-point 7
Improving capacity allocation with digital processing Advantages of digital processing Fixed Dynamic N = A + B + C 12 10 14 A 12 10 B 14 C India China India China South-East Asia South-East Asia Allocates capacity from one beam to another, increasing possible satellite configurations More processing equals more capacity which can be allocated to regions with high demand Shift towards smaller beams requires greater switch-ability 8
Delivering greater flexibility of market coverage SES-12, SES-14 and SES-15 HTS spot beam footprints SES-15 (129 West) Up to 10 GHz HTS SES-14 (47.5/48 West) Up to 12 GHz HTS SES-12 (95 East) Up to 14 GHz HTS + Spot beams laying down high volume of capacity globally Digital processing optimally allocating capacity to key areas = On-orbit capability to pivot from one market opportunity to another 9
Reducing normalised CapEx requirement Satellite and launch cost (at date of of contract placing) Cost per TPE per year (Dec-2009 = 100) 100 HTS capacity Dec-2009 Dec-2010 Dec-2011 Dec-2012 Dec-2012 Dec-2013 Dec-2014 0 2009 2010 2011 2012 2013 2014 Achieving ~12% programme cost savings; on track to deliver target of up to 20% by 2018 10
Globalised business with strong local presence SES s global satellite fleet and access network Industry-leading network performance (over 99.99% network availability) Unmatched technical understanding customer relationships (average 8.9/10 rating of technical excellence in customer service) 11
Keeping satellite at the heart of the global network Key advantages of satellite within the global communications network Wide coverage global footprint and unparalleled global reach Broadcast bit-efficient dissemination of data Instantaneous and scalable throughput new network node easily built with a new antenna Key attributes for satellite to remain at the heart of the digital ecosystem Switch-ability to adapt capacity to network need and maintain fill rates Cost efficiency of new capacity to maintain/enhance the attraction of satellite 12
Looking towards the next generation of innovation Today Tomorrow Hyperadvanced payloads Quadrupled processing power, means more capability to allocate capacity to meet future customer requirements Photonic-based front-end technologies reduce cost and mass for greater performance Multi-launch vehicles Fully reusable launch vehicles amortising rocket manufacturing costs over multiple payloads 13
Building SES s future technology infrastructure Future: Blue Sky Next Gen: Now Electric propulsion allows for larger satellites to be launched on smaller vehicles Selective payload processing builds in flexibility to market demand Qualifying new launch vehicles (Falcon 9) which diversify access to space Hybrid network offerings interconnecting SES s GEO coverage with low latency/low cost per bit of O3b Next Next Gen: 2019 Massively processed payloads optimising spectrum allocation Full digitisation means simpler, smaller, lighter payload manufacturing Fully reusable launch vehicles (Falcon 9-R) which amortises rocket costs over multiple missions Satellite at heart of universal global transparent network Upgradeable payloads leverage digital technology evolution rates Advanced launch strategies (e.g. space tugs ) maximising efficiency to orbit Allocation-specific programmable transponders allow payloads to be reconfigured in software on orbit 14
Conclusion Video Fixed Data Shaping future technology of the industry to enhance our core technical value SES s global satellite infrastructure remains integral to a global connected network SES is delivering the future of connectivity Mobility Government 15
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